辐射冷却
材料科学
润湿
热导率
水冷
保温
杰纳斯
发射率
复合材料
纳米技术
光电子学
光学
机械工程
气象学
物理
图层(电子)
工程类
作者
Shuangjiang Feng,Lei Yao,Xi Chen,Chenghuan Liu,Xiaohai Bu,Yuzhong Huang,Man He,Yuming Zhou
标识
DOI:10.1016/j.jcis.2023.05.185
摘要
All-weather personal thermal regulation has far been challenged by variable environments especially the regulatory failure caused by highly-dense solar radiation, low environmental radiation and the fluctuated epidermal moisture in different seasons. Herein, from the design of interface selectivity, dual-asymmetrically optical and wetting selective polylactic acid-based (PLA) Janus-type nanofabric is proposed to achieve on-demand radiative cooling and heating as well as sweat transportation. Hollow TiO2 particles are introduced in PLA nanofabric causing high interface scattering (∼99%) and infrared emission (∼91.2%) as well as surface hydrophobicity (CA>140°). The strictly optical and wetting selectivity help achieve ∼12.8℃ of net cooling effect under >1500 W/m2 of solar power and ∼5℃ of cooling advantage higher than cotton fabric and sweat resistance simultaneously. Contrarily, the semi-embedded Ag nanowires (AgNWs) with high conductivity (0.245 Ω/sq) endows the nanofabric with visible water permeability and excellent interface reflection for thermal radiation from body (>65%) thus causing ∼7℃ of thermal shielding. Through simple interface flipping, synergistical cooling-sweat reducing and warming-sweat resisting can be achieved to satisfy the thermal regulation in all weather. Compared with conventional fabrics, multi-functional Janus-type passive personal thermal management nanofabrics would be of great significance to the personal health maintenance and energy sustainability.
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